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GRASSLAND CLIMATES 69 the cloud, and the speed or direction of the wind may change at different heights inside the cloud. This process produces wind shear, a for ce that exists when the wind at a particular height blows across the path of the wind below it and at a greater speed. Wind shear sets the column of rising air ro- tating, so the air is spiraling upward. The rotation begins in the upper part of the cloud, below the level of wind shear. The rotating center of the cloud is then known as a mesocy- clone. The word cyclone describes air that rotates in the same direction as the Earth—counter clockwise in the Northern Hemisphere. Most mesocyclones rotate cyclonically (coun- terclockwise), but the reason for this is unclear and occasion- ally there are mesocyclones that turn in a clockwise direction (anticyclonically). Gradually more and more of the inside of the cloud begins to turn, and the rotation extends downward. At this stage the mesocyclone is up to five miles (8 km) across. Eventually the rotation may extend to the air immediately below the cloud. Air that is drawn into the up currents now starts turning as it approaches the cloud, so the mesocyclone consists of air that is spiraling upward to where it is swept into the anvil and removed. Because air is being removed, the atmospheric pressure inside the mesocyclone is low, and as air enters the spiral its pressure drops. The reduction in pressure allows the air to expand, causing it to cool, and its water vapor condenses. Condensation in the rotating air beneath the cloud base makes it look as though the cloud itself is descending. Its rotation is clearly visible from a distance, and fragments of cloud can be seen moving across it. The rotation continues to extend downward, and as it does so it becomes narrower. Visible because of the condensation it produces, the rotating column of air extends below the storm cloud as a funnel cloud, widest at the top and tapering toward the lower end. Air accelerates as it enters the spiral and the wind speed is greatest around the core of the funnel. The acceleration is due to a property of spinning objects. When it spins, an object possesses angular momentum that is proportional to its mass, speed of rotation (called its angular velocity), and radius of rotation. Its angular momentum remains constant, so if one of its components changes, one or more of the others changes to compensate. This is called the conservation of angular momentum. Air cannot alter its mass, but as it approaches the center of the funnel, its radius of spin decreases and consequently its angular velocity increases in proportion. It means that the wider the funnel, the greater the wind speeds around the center . If the funnel touches the ground it becomes a tornado— called a “cyclone” or a “twister” in some parts of the United States. T ornadoes sweep up dust and other debris to produce a dark cloud around the base of the funnel. As this material is carried upward and into the cloud, the tornado darkens. All tornadoes are dangerous. Even a mild one will lift debris and hurl it out of the spiral with great force, and all but the mildest tornadoes are capable of demolishing small buildings and throwing trailer homes and cars around as if they are toys. Tornadoes can happen anywhere and at any time, but they are more likely in some places and at some times. More than half of all tornadoes occur in spring. The season begins in February in the Gulf states. In March and April there are often tornadoes in Georgia and Florida. The greatest number, however, occur in May and June across the Great Plains. A belt extending from northern Texas and the Texas Panhandle through Oklahoma and Nebraska suffers more tornadoes than any other part of the country—or of the world. It is known as “Tornado Alley.” 70 GRASSLANDS 71 Evolution of grasslands Grasses first appeared on Earth about 60 million years ago. The earliest types, possibly related to modern bamboos, grew in the Tropics, in regions close to the forest edges where the climate was too dry for trees. As the map shows, at that time North America, Eurasia, and Africa were still joined and the early grasses were able to spread across the supercontinent. As the supercontinent broke apart, its animals and plants were carried away on the present-day continents. Plants and animals on one continent cannot breed with those on another continent separated from them by an ocean, so once the supercontinent had broken apart, the species on each continent began to evolve independently. All of the main groups of grasses had appeared before the separa- tion began, however, so each continent carried representa- tives of all the groups. No matter how living conditions changed, there was a good chance that among these groups there would be some types of grass that could prosper. The grasses thrived, and today there are about 9,000 species in the grass family (Poaceae). Some other plant families contain more species, but none dominates entire landscapes the way grasses do or thrives in such varied locations—everywhere from the edges of the Arctic and Antarctic Circles to the equa- tor and from high in the mountains to sea level. By about 45 million years ago there were grasses growing on all of the continents, but they were not yet abundant, especially in Australia, where grasses made up only a small proportion of the vegetation. Grasses were still confined to the Tropics, and they probably grew in forest clearings and around their edges. There were no grasslands like those of today. HISTORY OF GRASSLANDS CHAPTER 4 72 GRASSLANDS As the continents continued to separate, climates every- where slowly changed. There were periods of warmer weath- er, but the general trend was toward cooler conditions. The slow but steady fall in temperatures continued for millions of years, leading to the series of ice ages that began about 2.5 million years ago. Tropical climates remained warm, but the changes in wind patterns resulting from the redistribution of the continents and the widening of the oceans produced dry and rainy sea- sons over the interior of the tropical continents (see “Dry sea- sons and rainy seasons” on pages 51–55). Trees had difficulty adapting to dry winters and surviving occasional prolonged droughts. Grasses, however, were able to thrive in these con- ditions. The forests became smaller and grasses moved into the lands the trees had vacated. About 15 million years ago there were tropical grasslands in South America, and by 14 million years ago grassland cov- ered parts of what is now Kenya, in East Africa. These are the earliest grasslands for which scientists have fossil evidence. They were much less open than the modern savanna grass- land. The landscape was more like parkland, with some iso- lated trees and shrubs, scattered stands of trees, and grasses, together with a variety of other herbs, growing on the open ground between them. The world 65 million years ago. At that time North America, Eurasia, and Africa were joined. This proximity allowed grasses to spread freely. When the continents separated, they carried the grasses with them. The arrows represent the movement of grasses. HISTORY OF GRASSLANDS 73 As the global cooling continued and forests outside the Tropics contracted, grasses expanded away from the equator and temperate grasslands started to appear. Around the time the Kenyan grasslands were expanding, some of the tropical grasslands in South America were changing into temperate grasslands. Forests survived for much longer in North America. Grasses were widespread, but until about five million years ago they accounted for no more than about one-fifth of the total vegetation on the Great Plains. Then the grasses began to spread. It was not until about 2.5 million years ago, how- ever, that they had developed into the prairie that greeted the first humans to make their homes on the continent. The Eurasian steppe formed and expanded at about the same time. The continents continued to move, and about 3 million years ago North and South America met and joined. There were times when the climate grew warmer and tropical forests expanded through Central America, but at cooler times savanna grassland linked North and South America, allowing grassland animals to move from one continent to the other. Temperate grassland animals also migrated between North America and Eurasia, across a land bridge linking Alaska and Siberia across what is now the Bering Strait. Grasslands and past climate changes Grasses tolerate a wide range of climatic conditions, but occa- sionally even they are overwhelmed. About 2.5 million years ago the continuing fall in average temperatures reached an extreme. An ice age began. We know very little about this ice age. Evidence for it has been found in Britain and northwest- ern Europe but not in North America. Nevertheless, it is like- ly that the ice age affected the entire Northern Hemisphere. This was only the first of a series of ice ages that have been occurring ever since. There have probably been eight ice ages in all, and each one has lasted for tens of thousands or hun- dreds of thousands of years. Ice ages are separated by periods of warmer conditions, called interglacials. The most recent ice age—known as the Wisconsinian in North America, the Devensian in Britain, and the Weichselian in northwestern Europe—began about 75,000 years ago and ended about 10,000 years ago. Today we are living in the interglacial fol- lowing the end of the Wisconsinian, called the Holocene. Scientists divide the history of the Earth into episodes, as a geologic time scale (see “Geologic time scale” on page 32). There were ice ages in the more distant past, but the present series began toward the end of the Pliocene epoch and continued through the Pleistocene epoch. We are living 74 GRASSLANDS Holocene, Pleistocene, and late Pliocene glacials and interglacials Approximate date Northwestern (1,000 years BP) North America Great Britain Europe Holocene 10–present Holocene Holocene (Flandrian) Holocene (Flandrian) Pleistocene 75–10 Wisconsinian Devensian Weichselian 120–75 Sangamonian Ipswichian Eeemian 170–120 Illinoian Wolstonian Saalian 230–170 Yarmouthian Hoxnian Holsteinian 480–230 Kansan Anglian Elsterian 600–480 Aftonian Cromerian Cromerian complex 800–600 Nebraskan Beestonian Bavel complex 740–800 Pastonian 900–800 Pre-Pastonian Menapian 1,000–900 Bramertonian W aalian 1,800–1,000 Baventian Eburonian Pliocene 1,800 Antian Tiglian 1,900 Thurnian 2,000 Ludhamian 2,300 Pre-Ludhamian Pretiglian BP means “before present” (present is taken to be 1950). Names in italic refer to interglacials. Other names refer to glacials (ice ages). Dates become increasingly uncertain for the older glacials and interglacials and the period before about 2 million years ago. Evidence for these episodes has not been found in North America; in the case of the Thurnian glacial and Ludhamian interglacial the only evidence is from a borehole at Ludham, in eastern England. HISTORY OF GRASSLANDS 75 today in the Holocene epoch. The table lists the ice ages—the technical name for them is glacials—and interglacials from the present back through the Pleistocene and to the late Pliocene. Ice ages begin when summer temperatures fall by a few degrees. When this happens, some of the snow that fell in the previous winter fails to melt. Because it is white, the snow reflects sunshine—which would other wise warm the sur- face—and the ground beneath the snow remains cold. The following winter more snow falls on top of the snow that is still lying from the preceding winter, and the following sum- mer a slightly bigger area of snow fails to melt. In this way the snow-covered area gradually expands. Year by year the layer of snow grows thicker and heavier until the snow at the base of the layer is compressed so tightly it turns to ice. The ice then starts to spread outward. An advancing ice sheet scours away all of the soil and loose stones beneath it. Obviously no plants can survive beneath the ice—not even grass. Beyond the ice sheet there is a wide belt of tundra, where both the climate and the vegetation are similar to those found today in northern Canada and Siberia. During an ice age the climate everywhere is relatively dry. Such a large amount of water is stored permanently in the ice sheets that sea levels fall, leaving a smaller area of sea surface from which water can evaporate. At the same time low tem- peratures reduce both the rate of evaporation and the amount of water vapor that air is able to transport. Con- sequently, rainfall decreases, even in the Tropics. Tropical forests shrink in area, and savanna grasslands expand. Deserts also expand; during the Wisconsinian ice age, for example, the Sahara was much more extensive than it is today. When the ice age comes to an end, the ice sheets contract and the warmer conditions and rising sea levels mean that rainfall increases. The ground that was previously frozen throughout the year—the permafrost—thaws, and the tundra vegetation gives way to bushes and then to forest, except in the drier areas, where grassland predominates. Deserts also retreat. By about 9,000 years ago the Sahara had almost com- pletely disappeared. The desert was replaced by savanna grassland, which continued to occupy the area until about 5,000 years ago, when the climate became drier again and the desert returned. As the rainfall increased in the temperate regions and soils became deeper and richer, trees migrated northward. By about 7,000 years ago most of the lowlands throughout Western Europe and all of lowland Britain were covered by forest. During a period of warm, dry weather about 5,000 years ago, the prairie in North America expanded eastward as far as Ohio, with patches of grassland throughout the Midwest. But by about 3,000 years ago cooler, moister weath- er allowed forests of oak, chestnut, beech, and hemlock to become established. How forest can change into grassland The catalyst that converts forest to grassland is usually a change in the climate, but other factors can also play a part. The increased rainfall that allowed the North American forests to begin expanding into the prairie from about 3,000 years ago might have allowed them to expand farther had it not been for the bison. Similarly the tropical savannas of Africa might occupy a smaller area than they do were it not for the herds of grazing animals that live there. Large plant-eating animals, such as bison and antelope, feed on grass and herbs growing with the grass, but they will also eat the leaves and tender young shoots of trees and shrubs. They only eat those parts of the plants that they are able to reach, so the taller plants can survive, but not young seed- lings. Those are destroyed when they are eaten or trampled. Trees and shrubs grow from seeds, and destroying young plants reduces the number of future seed producers. As seeds stored in the soil sprout, grow a little, and are then killed, the store of seeds is steadily reduced. Thus when the mature plants that produced the seeds die of old age, there are no young plants to take their place. Grasses actually benefit from grazing, so they thrive as the shrubs and trees disappear. Grazing animals feed on grass, so they also benefit. The increased food supply means that more of their young survive, and with more animals to graze, the 76 GRASSLANDS HISTORY OF GRASSLANDS 77 woody plants are suppressed even more severely. Once the area of grassland is large enough to support large herds of grazers, the animals will prevent the grassland from changing to forest. Fire also helps grassland remain grassland. During the dry season tropical grasses die down, covering the ground with dry grass that the smallest spark will ignite. Fires are common and beneficial. They remove the dead plant matter and leave behind a layer of ash, rich in nutrients, that is washed into the ground by the first rain. With no layer of dead grass to suppress the new growth, the rain yields a flush of lush, nutritious grass. Trees and shrubs are more likely to be killed by the fire. Although their seeds below ground remain unharmed, by the time they produce shoots above ground the grasses are flourishing and the grazers are feeding. Humans may also play a part in maintaining grassland. They depend on the game animals and use fire as a tool to Fire on the Okavango delta, Botswana. Fires sweep unchecked across up to 70 percent of this grassland each year. (Courtesy of Frans Lanting/ Minden Pictures) hunt them. Large animals flee from fire, and hunters can exploit this behavior to make hunting easier. A group of hunters hides downwind of the herd, so the animals can neither see nor smell them; other members of the team then set a fire along a line at right angles to the wind; the wind directs the fire and the animals flee before it into the prepared ambush. After the fire has died down the grasses soon reappear. Over many years this technique will main- tain the grassland and expand its area by pushing back the edges of the forest, thereby providing more food for game animals. The transformation of New Zealand About 1,500 years ago Polynesian peoples were traveling across the Pacific Ocean and settling the habitable islands. In about the year 850 they reached New Zealand, the most southerly point in their explorations. They remained there, isolated from the rest of the world, for almost 1,000 years. Abel Janszoon Tasman (ca. 1603–ca. 1659), the Dutch navi- gator who also discovered Tasmania, Fiji, and Tonga, sighted South Island in December 1642, but when he attempted to land, the island’s inhabitants drove off his party and killed several of his men. The next European to visit the islands was the English explorer Captain James Cook (1728–79). In 1769–70 Cook sailed around both islands, mapping their coastlines and charting their coastal waters. Cook landed and eventually established good relations with the Maori people. Cook returned to New Zealand several times, exploring and mapping much of the country. He and other explorers found that approximately half of New Zealand was forested. Of the remainder, some was mountainous and lay above the tree line, but substantial areas were covered with grassland, scrub, and bracken. The map shows the area of forest in about 1850. The amount of forest was surprising, not because it was so extensive, but because it was so restricted. New Zealand has a climate that is ideal for trees, ranging from moist subtropical in the northern part of North Island to cool temperate in 78 GRASSLANDS [...]... internode, and especially the sensitive meristem cells at the base of the internode In most grass species the edges of the sheath are not joined, so the leaf can be prized open At the top of the sheath is a small structure called a ligule In some species the ligule consists only of hairs or is absent altogether Above the ligule the upper part of the leaf, called the blade, grows outward from the culm Blades... flattened The nodes are solid, but the internodes the sections of the culms between nodes—are either hollow or filled with pith (as they are in maize and sugarcane) The diagram shows the culm and the way the leaves are attached to it At the base of each internode there are cells that divide rapidly, constantly lengthening the culm These meristem cells are the first secret of every grass’s success They cause... run parallel to each other along the length of the leaf; this is a feature of all monocots Because the leaf grows from the node at its base, if grazing or mowing removes the upper part of the blade, the leaf soon grows back LIFE ON THE GRASSLANDS Most grasses have a single culm, but some tropical grasses, especially bamboos, produce branches from the nodes along the upper part of the culm Some tropical... rubisco) catalyzes the reaction In a cycle of reactions the carbon atoms, originally from the carbon dioxide, are combined with hydrogen obtained from NADPH; the NADP then returns to the lightdependent stage The cycle ends with the synthesis of molecules of glucose and of RuBP The RuBP is then available to commence the cycle again Glucose, a simple sugar, is the most common source of energy for living... consists of a series of modified leaves or bracts in two ranks borne on either side of a short axis called a rachilla (hidden in the drawing) The two lowest bracts are called glumes, and one is higher on the spikelet than the other The bracts above the glumes are called lemmas, and they bear flowers in their axils the places where the lemmas are attached to the rachilla The culms and blades of all grasses... grasses, and they lived mainly in the forests The Maori hunted them, eventually to extinction, possibly burning the forest to drive the birds into the open The climate on the eastern side of South Island is somewhat drier than that in the west This dryness might have made the forest burn more readily The destruction reached a peak between about 1150 and 1350 By the time Captain Cook landed, half of the original... by the wind Others have hooked or barbed bristles, called awns, at the ends of their glumes These bend and straighten in response to wetting and drying; as they do so, they pull the seed away from the parent plant and then tuck it below the soil surface Equipped as grasses are with such an impressive set of survival characteristics, it is no wonder that they have spread to almost every corner of the. .. pages 94 95) The moist pampas lie on the eastern side of the continent, and the climate becomes progressively drier farther to the west Despite the similarity, however, there is one important difference: The moist pampa has a wetter climate than the eastern, tallgrass prairie Consequently, South American tallgrasses are rather taller than their prairie equivalents When the first Spaniards arrived at the. .. This completes the light-dependent stage (continues) 86 GRASSLANDS (continued) Light-independent stage Using ATP from the light-dependent stage as a source of energy, the first in a series of chemical reactions attaches molecules of carbon dioxide (CO2) obtained from the air to molecules of ribulose biphosphate (RuBP), a substance present in the chloroplast The enzyme RuBP carboxylase (the name is usually... similar, but there are many different arrangements of the spikelets, and these are important aids to identifying species 89 LIFE ON THE GRASSLANDS The flowers are pollinated by the wind and each floret produces a single seed The seed usually is small and incorporates part of the floret, but not always Some bamboos, for instance, bear nutlike fruits, and others produce berries that are the size of small . The blade (leaf) grows from a node on the culm (stem). The lower part of the blade forms a sheath surrounding the culm. The ligule is a small structure at the top of the sheath. LIFE ON THE GRASSLANDS. across the path of the wind below it and at a greater speed. Wind shear sets the column of rising air ro- tating, so the air is spiraling upward. The rotation begins in the upper part of the cloud,. each other along the length of the leaf; this is a feature of all monocots. Because the leaf grows from the node at its base, if grazing or mowing removes the upper part of the blade, the leaf